Cortical integration in the visual system of the macaque monkey: large-scale morphological differences in the pyramidal neurons in the occipital, parietal and temporal lobes.

Layer III pyramidal neurons were injected with Lucifer yellow in tangential cortical slices taken from the inferior temporal cortex (area TE) and the superior temporal polysensory (STP) area of the macaque monkey. Basal dendritic field areas of layer III pyramidal neurons in area STP are significantly larger, and their dendritic arborizations more complex, than those of cells in area TE. Moreover, the dendritic fields of layer III pyramidal neurons in both STP and TE are many times larger and more complex than those in areas forming 'lower' stages in cortical visual processing, such as the first (V1), second (V2), fourth (V4) and middle temporal (MT) visual areas. By combining data on spine density with those of Sholl analyses, we were able to estimate the average number of spines in the basal dendritic field of layer III pyramidal neurons in each area. These calculations revealed a 13-fold difference in the number of spines in the basal dendritic field between areas STP and V1 in animals of similar age. The large differences in complexity of the same kind of neuron in different visual areas go against arguments for isopotentiality of different cortical regions and provide a basis that allows pyramidal neurons in temporal areas TE and STP to integrate more inputs than neurons in more caudal visual areas.     

Histamine in endocrine cells in the stomach. A survey of several species using a panel of histamine antibodies

Antibodies to histamine were used to examine the localization of the amine in cells of the stomach and upper small intestine of a great variety of species, including cartilaginous and bony fish, amphibia, reptiles (lizard), birds (chicken) and a large number of mammals. In all species gastric histamine was localized in endocrine cells (invariably found in the epithelium) and mast cells (usually with an extra-epithelial localization). The endocrine cells were identified as such by immunostaining with antibodies to chromogranin A and the mast cells were identified by toluidine blue staining. Histamine-immunoreactive endocrine cells were found almost exclusively in the acid-producing part of the stomach; only rarely were such cells observed in the pyloric gland area. They were fairly numerous in the gastric mucosa of the two subclasses of fish as well as in the amphibia and reptile species studied. Here, the majority of the histamine-immunoreactive endocrine cells seemed to have contact with the gastric lumen (open type cells) and were located in the surface epithelium (certain fish only) or together with mucous neck cells at the bottom of the pits. In the chicken, histamine-immunoreactive endocrine cells were numerous and located peripherally in the deep compound glands. They were without contact with the lumen (closed type) and had long basal extensions ("paracrine" appearance), running close to the base of the oxyntic-peptic cells. In mammals, the number of histamine-immunoreactive endocrine cells in the stomach varied greatly. They were particularly numerous in the rat and notably few in the dog, monkey and man. In all mammals, the histamine-immunoreactive endocrine cells were of the closed type and located basally in the oxyntic glands. They often had a "paracrine" appearance with long basal processes. Histamine-storing mast cells, finally, were few in both subclasses of fish as well as in the amphibian species and in the lizard. They were fairly numerous in chicken proventriculus (beneath the surface epithelium), few in the oxyntic mucosa of mouse, rat and hamster, moderate in number in hedgehog, guinea-pig, rabbit, pig and monkey, and numerous in cat, dog and man.(ABSTRACT TRUNCATED AT 400 WORDS)     

Innervation of the knee joint in the rabbit and the Formosan rock-monkey (Macaca cyclopis): a retrograde HRP study.

The number and segmental distribution of cell bodies of sensory afferents and sympathetic efferent innervating to the knee joint of the rabbit and the Formosan rock-monkey were investigated using retrograde transport with horseradish peroxidase (HRP). After injecting HRP into the articular knee joint capsule of the rabbits, labeled neurons were found in the ipsilateral L4-S2 dorsal root ganglia (DRG). However, following injection of HRP into the articular cavity of the knee joint in the rabbit and the monkey, labeled neurons were found in both the ipsilateral DRG (L5-S2 and L4-S1 of the rabbit and monkey, respectively) and in the ipsilateral sympathetic ganglia (SG) (L4-S3 (rabbit) and L3-S1 (monkey)). The majority of labeled neurons within the DRG and the SG were composed of medium and large neurons in the monkey and the rabbit, respectively. The present findings suggest that the sensory projections from and sympathetic projection to the knee joint in rabbits and monkeys are similar, but that both projections of monkeys were "shifted" one segment cranially compared to the rabbit on both projections.     

Morphological analysis of the neurons in the area of the hypothalamic magnocellular dorsal nucleus of the guinea pig

Summary In the guinea-pig hypothalamus, a group of enkephalinergic cells forms a well-circumscribed nuclear area called the magnocellular dorsal nucleus (MDN). This nucleus gives rise to a prominent projection to the lateral spetum: the hypothalamo-septal enkephalinergic pathway. In the present study, MDN neurons visualized by Golgi impregnation were subjected to morphological analysis in order to define the potential segregation of cellular types within the MDN. This study was complemented by additional observations of MDN neurons intracellularly injected by Lucifer yellow (LY) or horseradish peroxidase (HRP) during the in vitro incubation of hypothalamic slices. The following results were obtained from the analysis of 200 neurons: 163 Golgi-impregnated cells plus 37 injected cells (LY=14; HRP=23). Thirteen HRP-injected cells were precisely located in the MDN and 10 were located in the perifornical area surrounding the MDN. Four different cellular types were identified. Type-I neurons (41%) displayed a globular perikaryon, a variable number of primary dendrites that were poorly ramified, no preferential orientation, and an axon emerging from the perikaryon. Type-II neurons (30.5%) had a triangular perikaryon, three well-ramified primary dendrites, an orientation perpendicular to the third ventricle, and an axon emerging from the perikaryon. Type-III neurons (22%) exhibited a spindle-shaped perikaryon, two opposed well-ramified primary dendrites, an orientation perpendicular to the third ventricle, and an axon emerging from a primary dendrite. Type-IV neurons (6.5%), showed a globular perikaryon, a variable number of primary dendrites, poorly ramified dendrites, an orientation parallel to the third ventricle, and an axon whose orientation could not be identified. Neurons labeled after intracellular injection belonged to the first three cellular types.     

Distribution of motor cortical neuron synaptic terminals on monkey parvocellular red nucleus neurons.

We determined the location of 54 horseradish peroxidase (HRP)-labeled motor cortical neuron synaptic terminals on 17 parvocellular neurons in the monkey red nucleus. Synaptic terminals and their postsynaptic elements were identified and reconstructed, using light- and electron-microscopic techniques, from serial thick and thin sections. Terminals were found on proximal and distal dendrites of small and medium-sized parvocellular neurons, where they formed excitatory synapses. Some were 180 microns from cell somata. Approximately half of the labeled terminals, aside from those located at dendritic origins, were situated strategically at or near dendritic branch points. Since monkey parvocellular neurons show little activity during movement, the obvious next question is this: How and in what way does motor cortex influence these cells?     

Distribution of Motor Cortical Neuron Synaptic Terminals on Monkey Parvocellular Red Nucleus Neurons

We determined the location of 54 horseradish peroxidase (HRP)-labeled motor cortical neuron synaptic terminals on 17 parvocellular neurons in the monkey red nucleus. Synaptic terminals and their postsynaptic elements were identified and reconstructed, using light- and electron-microscopic techniques, from serial thick and thin sections. Terminals were found on proximal and distal dendrites of small and medium-sized parvocellular neurons, where they formed excitatory synapses. Some were 180 μm from cell somata. Approximately half of the labeled terminals, aside from those located at dendritic origins, were situated strategically at or near dendritic branch points. Since monkey parvocellular neurons show little activity during movement, the obvious next question is this: How and in what way does motor cortex influence these cells?     

Comparative analysis of NADPH-diaphorase positive neurons in the rat, rabbit and pheasant thoracic spinal cord. A histochemical study.

The distribution of NADPH-diaphorase (NADPH-d) activity was investigated and compared in the rat, rabbit and pheasant thoracic spinal cord. The investigation of all spinal cord regions (laminae) in three experimental species revealed marked differences in the distribution of NADPH-d activity. Cross sectional analysis of the spinal cord of the rat, rabbit and pheasant confirmed differences in the shape of the gray matter in all examined species. More detailed investigation of Rexed's laminas showed similar distribution of NADPH-d activity in the spinal cord of the rat and rabbit, which were different when compared with the spinal cord of the pheasant. Ventral horn of the rat and rabbit showed no labelling whereas in pheasant this area possessed a number of scattered, intensively stained neurons. In the location of autonomic preganglionic neurons, differences were found as well. In the rat there was seen a number of densely packed, clearly dark blue coloured neurons. Similarly, these neurons were present in the rabbit spinal cord but they were less numerous. No staining was found in this region of pheasant. Pericentral area (lamina X) and intermediate zone (laminaVII) revealed the presence of NADPH-d positive neurons in all examined species although they differed in number and shape of their bodies. The dorsal horn showed the presence of NADPH-d staining in all three animals but its distribution was different in medio-lateral direction. It can be suggested that observed differencies in the presence and distribution of NADPH-d activity across the examined species may reflect different fylogenetic development.     

Localisation of substance P-like immunoreactivity in the ciliary ganglia of monkey (Macaca fascicularis) and cat: a light- and electron-microscopic study

The present study describes substance P-like immunoreactivity in the ciliary ganglia of monkey (Macaca fascicularis) and cat. About 60% of neurons in the monkey ciliary ganglion and 40% in the cat ciliary ganglion were substance P-like immunoreactive, ranging from faint to moderate staining. Substance P-like immunoreactivity was located in cell bodies, dendritic profiles and axons. In the monkey, substance P-like immunoreactive pericellular arborisations were associated with about 0.5%–3% of the ganglion cells, which were either negatively, faintly or moderately stained. An electron-microscopic study demonstrated the presence of either substance P-like immunoreactive positive or negative axon terminals synapsing or closely associated with positive dendritic profiles in both the monkey and cat ciliary ganglia. The results suggest that substance P plays an important role in the ciliary ganglion, perhaps as a modulator or transmitter.     

Nature of the distribution of synapses in the neurons of the reticular formation and some afferent nuclei]

Under study was the morphology of synaptic terminations of the brain reticular formation in cats and dogs as well as that of the afferent nuclei of the cat's posterior columns. The neurons of the Goll's and Burdach's nuclei have a richly ramified dendritic network. In this connection the main mass of synapses is disposed on the dendrites and their different branchings. The dendrites of the multipolar cells of the reticular formation have the main type of branching, but the cells are distributed from the nerve cell body at a considerable distance (up to 50 mu and more). The synapses are observed at the total length of the dendrite, so the axo-dendritic contacts quantitatively prevail over axo-somatic ones. The morphological data are compared with physiological axo-somatic and axo-dendritic concepts of the role of synapses in conducting the nerve impulse.     

MHC class II antigen-expressing cells in cardiac ganglia of the rat

Cardiac ganglia develop destructive ganglionitis in chronic Chagas disease and rheumatic heart disease. This ganglionitis is associated with periganglionic infiltrations and is suspected of developing secondary to epicardial inflammation. If so, it would be expected that cardiac ganglia (1) are equipped with an inventory of immune competent cells allowing the initiation of inflammatory processes, and (2) are not effectively protected from the milieu of the surrounding tissue by metabolically active diffusion barriers. These problems were addressed in specified pathogen-free rats by electron microscopy and immunohistochemistry with markers for dendritic cells, monocytes/macrophages, and perineurial barriers. In contrast to nerve fascicles, cardiac ganglia are only partially enveloped by perineurial cells. Inside the ganglia, ramified cells with major histocompatibility complex class II antigen (reacting with monoclonal antibody OX6) on their surface and exhibiting an ultrastructure typical of dendritic cells are numerous, comprising nearly 5% of all cells within ganglia. The ratio of the number of these cells to that of neurons is 1:2. Cells reacting with monoclonal antibodies ED1 and ED2, markers for monocytes/macrophages, constitute 1.8% and 1.6% of the ganglionic cell population, respectively. Such cells are less frequent in the cervical trunk of the vagus nerve. Thus, the inventory of immune competent cells in rat cardiac ganglia is consistent with the view that the abundance of antigen-presenting cells correlates with the permeability of the barriers providing protection from blood-borne and tissue-borne factors.     

Species differences in the aromatization of quinic acid in vivo and the role of gut bacteria

1. The fate of (−)-quinic acid has been investigated in 22 species of animals including man. 2. In man and three species of Old World monkeys, i.e. rhesus monkey, baboon and green monkey, oral quinic acid was extensively aromatized (20–60%) and excreted in the urine as hippuric acid, which was determined fluorimetrically. 3. In three species of New World monkeys, i.e. squirrel monkey, spider monkey and capuchin, in three species of lemurs, i.e. bushbaby, slow loris and tree shrew, in the dog, cat, ferret, rabbit, rat, mouse, guinea pig, hamster, lemming, fruit bat, hedgehog and pigeon, oral quinic acid was not extensively aromatized (0–5%). 4. In the rhesus monkey, injected quinic acid was not aromatized, but largely excreted unchanged. 5. In rhesus monkeys pretreated with neomycin to suppress gut flora, the aromatization of oral quinic acid was considerably suppressed. 6. In rats and rhesus monkeys [¹⁴C]quinic acid was used and this confirmed its low aromatization in rats and its high aromatization in the monkeys. 7. Shikimic acid given orally was excreted as hippuric acid (26–56%) in rhesus monkeys, but not in rats. 8. The results support the view that quinic acid and shikimic acid are aromatized by the gut flora in man and the Old World monkeys.     

The fate of benzoic acid in various species

1. The urinary excretion of orally administered [¹⁴C]benzoic acid in man and 20 other species of animal was examined. 2. At a dose of 50mg/kg, benzoic acid was excreted by the rodents (rat, mouse, guinea pig, golden hamster, steppe lemming and gerbil), the rabbit, the cat and the capuchin monkey almost entirely as hippuric acid (95–100% of 24h excretion). 3. In man at a dose of 1mg/kg and the rhesus monkey at 20mg/kg benzoic acid was excreted entirely as hippuric acid. 4. At 50mg/kg benzoic acid was excreted as hippuric acid to the extent of about 80% of the 24h excretion in the squirrel monkey, pig, dog, ferret, hedgehog and pigeon, the other 20% being found as benzoyl glucuronide and benzoic acid, the latter possibly arising by decomposition of the former. 5. On increasing the dose of benzoic acid to 200mg/kg in the ferret, the proportion of benzoyl glucuronide excreted increased and that of hippuric acid decreased. This did not occur in the rabbit, which excreted 200mg/kg almost entirely as hippuric acid. It appears that the hedgehog and ferret are like the dog in respect to their metabolism of benzoic acid. 6. The Indian fruit bat produced only traces of hippuric acid and possibly has a defect in the glycine conjugation of benzoic acid. The main metabolite in this animal (dose 50mg/kg) was benzoyl glucuronide. 7. The chicken, side-necked turtle and gecko converted benzoic acid mainly into ornithuric acid, but all three species also excreted smaller amounts of hippuric acid.     

Ectopic Purkinje cells in the cerebellar white matter of normal adult rodents: a Golgi study

In Golgi/Río-Hortega preparations of rat and rabbit cerebellar vermis we have occasionally found isolated ectopic Purkinje cells in the white matter. They were located beneath the bases of the folia and their dendritic branches extended within the confines of the white matter without penetrating into the overlying cortical layers. The general morphology of these ectopic cells was variable, particularly in the extension and shape of the dendritic trees, but all of them exhibited a lower density of dendritic branches than normal Purkinje cells. The less-developed ectopic neurons had multipolar dendritic trees with nonplanar branches irregularly studded with spines. The well-developed ones displayed a more extensive arborization of their processes and they usually preserved some morphological features of normal cortical Purkinje cells: distal dendritic branches studded with numerous spines, a pear-shaped soma, clearly defined morphological polarity and a tendency to display planar arrangement of the dendritic arbors. In semithin sections these neurons also showed cytological features of normal Purkinje cells, such as the Nissl substance forming a nuclear cap oriented toward the dendritic pole. We suggest that the abnormal location of the neurons results from a disorder of Purkinje cell migration which occurs naturally during the prenatal development of the cerebellum. The possible morphogenetic mechanisms involved in the migration and differentiation of these ectopic neurons are also discussed.     

The fine structure of supraoptic neurons of hedgehogs

Summary Supraoptic neurons of the hedgehog contain round osmiophilic inclusions similar to those described in neurosecretory neurons of other species. They also contain elongated crystal-like bodies, which have hitherto only been observed in the distal parts of neurohypophysial nerve fibres, and only in the hedgehog. The observations reported here suggest that two distinct types of neurosecretory inclusion may be elaborated within a single cell.     

Ribosomal ribonucleic acids of cultured cells: A preliminary survey of differences among mammalian species detectable by polyacrylamide gel electrophoresis

Summary Ribosomal ribonucleic acids (rRNA's) of cultured cells from various species were compared by polyacrylamide gel electrophoresis. Electrophoretic mobility of the 28 S RNA component varied according to species. Human cell 28 S rRNA was distinguishable from that of monkey cells. The mobility of chimpanzee 28 S rRNA was identical to that from human cells, but different from that of monkey cells. Cat, goat, and swine cell 28 S rRNA's were distinguishable from one another and from both human and monkey cell rRNA's. The mobilities of bovine, rabbit, rat, hamster, and mouse cell 28 S rRNA's were virtually identical to that from monkey cells. No apparent correlation existed between the mobility of 28 S rRNA and the currently accepted phylogenetic position of the donors. Normal cells, tumor cells, and virus-infected cells from the same species did not differ, but in some instances embryonic and adult cells were distinguishable. The 18 S rRNA components did not show variations comparable to those of the 28 S rRNA components. This work was supported by the Office of Naval Research and the Bureau of Medicine and Surgery, United States Navy, under a contract between the Office of Naval Research and the Regents of the University of California.     

Distribution of unipolar brush cells and other calretinin immunoreactive components in the mammalian cerebellar cortex

We have compared the distribution of unipolar brush cells (UBCs) in the cerebellum of Brazilian opossum (Monodelphis domestica), mouse, guinea pig, rabbit, cat, and Rhesus monkey, using an antiserum to calretinin which is present in those cells. The morphology and calretinin staining intensity of the UBCs remains constant across species. As a general trend, in all species studied, UBCs are particularly enriched in the vestibulocerebellum. Interspecies differences, however, were noted in the distribution of UBCs across other regions of the cerebellar cortex. A major variation involves the extent of the UBC-rich region of the ventral portion of the paraflocculus. The distribution of UBCs in non-vestibular vermal folia also varies substantially. UBCs are deployed in more or less distinct parasagittal zones in the vermis of the opossum, rabbit, cat, and macaque. The density of UBCs decreases progressively from medial to lateral portions of the same folium and is lowest in the lateral, posterior portions of the cerebellar hemispheres (crus II) and in the dorsal portion of the paraflocculus. In cat and macaque, the decrease in the density of UBCs across the intermediate cortex is more gradual than in the other species. The data indicate that the UBCs play a more prominent role in the modulation of sensorimotor transformations in carnivores and primates than in smaller mammals and should not be considered a vestigial form of neuron. In addition to the UBCs, calretinin antibody distinctly stains the following neurons in different species: granule cells and parallel fibers in all species except rabbit and cat; Golgi cells, especially in rat and macaque; Lugaro-like cells, especially in mouse, rat, and macaque; basket cells in macaque; subsets of mossy fibers in all species; and subsets of climbing fibers in all species but guinea pig. Usually, the distribution of UBCs is related to that of calretinin stained granule cells and mossy fibers.     

Morphology of calretinin and tyrosine hydroxylase-immunoreactive neurons in the pig retina

The morphology of calretinin- and tyrosine hydroxylase-immunoreactive (IR) neurons in adult pig retina was studied. These neurons were identified using antibody immunocytochemistry. Calretinin immunoreactivity was found in numerous cell bodies in the ganglion cell layer. Large ganglion cells, however, were not labeled. In the inner nuclear layer, the regular distribution of calretinin-IR neurons, the inner marginal location of their cell bodies in the inner nuclear layer, and the distinctive bilaminar morphologies of their dendritic arbors in the inner plexiform layer suggested that these calretinin-IR cells were AII amacrine cells. Calretinin immunoreactivity was observed in both A-and B-type horizontal cells. Neurons in the photoreceptor cell layer were not labeled by this antibody. The great majority of tyrosine hydroxylase-IR neurons were located at the innermost border of the inner nuclear layer (conventional amacrines). The processes were monostratified and ran laterally within layer 1 of the inner plexiform layer. Some of the tyrosine hydroxylase-IR neurons were located in the ganglion cell layer (displaced amacrines). The processes of displaced tyrosine hydroxylase-IR amacrine cells were also located within layer 1 of the inner plexiform layer. Some processes of a few neurons were located in the outer plexiform layer. A very low density of neurons had additional bands of tyrosine hydroxylase-IR processes in the middle and deep layers of the inner plexiform layer. The processes of tyrosine hydroxylase-IR neurons extended radially over a wide area and formed large, moderately branched dendritic fields. These processes occasionally had varicosities and formed "dendritic rings". These results indicate that calretinin- and tyrosine hydroxylase-IR neurons represent specific neuronal cell types in the pig retina.     

Effects of low temperature on contraction in papillary muscles from rabbit, rat, and hedgehog

During hibernation the body temperature may fall to only a few degrees above 0 degree C. The heart of the hedgehog continues to function whereas the hearts of nonhibernating mammals stop beating. The present study was performed to investigate and compare the mechanical responses to hypothermia in rabbits, rats, and hedgehogs. Isometric force was recorded from papillary muscles mounted in an organ bath and effects of hypothermia on the mechanical restitution curve were also compared. A reduction of bath temperature from 35 degrees C caused an increase in peak developed force. Maximum force was seen at 20 degrees C in the rabbit, 15 degrees C in the rat, and 10 degrees C in the hedgehog preparations. In all the species there was a similar prolongation of time to peak force and of time from peak to half-relaxation as temperature was lowered. An increase in resting force and after-contractions were recorded in the rabbit and rat muscles at temperatures below 15 and 10 degrees C, respectively. The rabbit and rat preparations became inexcitable at temperatures below 10 and 5 degrees C, respectively. The hedgehog papillary muscle, on the other hand, still contracted at 0 degree C and did not show increased resting force nor after-contractions. The results are consistent with the hypothesis that there is a calcium overload in cardiac cells from rabbit and rat at low temperatures but there is no calcium overload in the hedgehog muscle during hypothermia.     

A model for the neuronal implementation of selective visual attention based on temporal correlation among neurons

We propose a model for the neuronal implementation of selective visual attention based on temporal correlation among groups of neurons. Neurons in primary visual cortex respond to visual stimuli with a Poisson distributed spike train with an appropriate, stimulus-dependent mean firing rate. The spike trains of neurons whose receptive fields donot overlap with the focus of attention are distributed according to homogeneous (time-independent) Poisson process with no correlation between action potentials of different neurons. In contrast, spike trains of neurons with receptive fields within the focus of attention are distributed according to non-homogeneous (time-dependent) Poisson processes. Since the short-term average spike rates of all neurons with receptive fields in the focus of attention covary, correlations between these spike trains are introduced which are detected by inhibitory interneurons in V4. These cells, modeled as modified integrate-and-fire neurons, function as coincidence detectors and suppress the response of V4 cells associated with non-attended visual stimuli. The model reproduces quantitatively experimental data obtained in cortical area V4 of monkey by Moran and Desimone (1985).